Optimization of energy state transition trajectory supports the development of executive function during youth

Zaixu Cui; Jennifer Stiso; Graham L. Baum; Jason Z. Kim; David R. Roalf; Richard F. Betzel; Shi Gu; Zhixin Lu; Cedric H. Xia; Xiaosong He; Rastko Ciric; Desmond J. Oathes; Tyler M. Moore; Russell T. Shinohara; Kosha Ruparel; Christos Davatzikos; Fabio Pasqualetti; Raquel E. Gur; Ruben C. Gur; Danielle S. Bassett; Theodore D. Satterthwaite

doi:10.7554/eLife.53060

Optimization of energy state transition trajectory supports the development of executive function during youth

Zaixu Cui
, Jennifer Stiso
, Graham L. Baum
, Jason Z. Kim
, David R. Roalf
, Richard F. Betzel
, Shi Gu
, Zhixin Lu
, Cedric H. Xia
, Xiaosong He
, Rastko Ciric
, Desmond J. Oathes
, Tyler M. Moore
, Russell T. Shinohara
, Kosha Ruparel
, Christos Davatzikos
, Fabio Pasqualetti
, Raquel E. Gur
, Ruben C. Gur
, Danielle S. Bassett

Theodore D. Satterthwaite

Research output: Contribution to journal › Article › peer-review

66 Scopus citations

Abstract

Executive function develops during adolescence, yet it remains unknown how structural brain networks mature to facilitate activation of the fronto-parietal system, which is critical for executive function. In a sample of 946 human youths (ages 8-23y) who completed diffusion imaging, we capitalized upon recent advances in linear dynamical network control theory to calculate the energetic cost necessary to activate the fronto-parietal system through the control of multiple brain regions given existing structural network topology. We found that the energy required to activate the fronto-parietal system declined with development, and the pattern of regional energetic cost predicts unseen individuals’ brain maturity. Finally, energetic requirements of the cingulate cortex were negatively correlated with executive performance, and partially mediated the development of executive performance with age. Our results reveal a mechanism by which structural networks develop during adolescence to reduce the theoretical energetic costs of transitions to activation states necessary for executive function.

Original language	English (US)
Pages (from-to)	1-60
Number of pages	60
Journal	eLife
Volume	9
DOIs	https://doi.org/10.7554/eLife.53060
State	Published - Mar 2020
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2020, eLife Sciences Publications Ltd. All rights reserved.

Keywords

Adolescence
Development
Diffusion MRI
Energy
Network

Publisher link

10.7554/eLife.53060

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Cui, Z., Stiso, J., Baum, G. L., Kim, J. Z., Roalf, D. R., Betzel, R. F., Gu, S., Lu, Z., Xia, C. H., He, X., Ciric, R., Oathes, D. J., Moore, T. M., Shinohara, R. T., Ruparel, K., Davatzikos, C., Pasqualetti, F., Gur, R. E., Gur, R. C., ... Satterthwaite, T. D. (2020). Optimization of energy state transition trajectory supports the development of executive function during youth. eLife, 9, 1-60. https://doi.org/10.7554/eLife.53060

Cui, Z, Stiso, J, Baum, GL, Kim, JZ, Roalf, DR, Betzel, RF, Gu, S, Lu, Z, Xia, CH, He, X, Ciric, R, Oathes, DJ, Moore, TM, Shinohara, RT, Ruparel, K, Davatzikos, C, Pasqualetti, F, Gur, RE, Gur, RC, Bassett, DS & Satterthwaite, TD 2020, 'Optimization of energy state transition trajectory supports the development of executive function during youth', eLife, vol. 9, pp. 1-60. https://doi.org/10.7554/eLife.53060

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title = "Optimization of energy state transition trajectory supports the development of executive function during youth",

abstract = "Executive function develops during adolescence, yet it remains unknown how structural brain networks mature to facilitate activation of the fronto-parietal system, which is critical for executive function. In a sample of 946 human youths (ages 8-23y) who completed diffusion imaging, we capitalized upon recent advances in linear dynamical network control theory to calculate the energetic cost necessary to activate the fronto-parietal system through the control of multiple brain regions given existing structural network topology. We found that the energy required to activate the fronto-parietal system declined with development, and the pattern of regional energetic cost predicts unseen individuals{\textquoteright} brain maturity. Finally, energetic requirements of the cingulate cortex were negatively correlated with executive performance, and partially mediated the development of executive performance with age. Our results reveal a mechanism by which structural networks develop during adolescence to reduce the theoretical energetic costs of transitions to activation states necessary for executive function.",

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doi = "10.7554/eLife.53060",

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AU - Cui, Zaixu

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AU - Betzel, Richard F.

AU - Gu, Shi

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AU - Xia, Cedric H.

AU - He, Xiaosong

AU - Ciric, Rastko

AU - Oathes, Desmond J.

AU - Moore, Tyler M.

AU - Shinohara, Russell T.

AU - Ruparel, Kosha

AU - Davatzikos, Christos

AU - Pasqualetti, Fabio

AU - Gur, Raquel E.

AU - Gur, Ruben C.

AU - Bassett, Danielle S.

AU - Satterthwaite, Theodore D.

PY - 2020/3

Y1 - 2020/3

N2 - Executive function develops during adolescence, yet it remains unknown how structural brain networks mature to facilitate activation of the fronto-parietal system, which is critical for executive function. In a sample of 946 human youths (ages 8-23y) who completed diffusion imaging, we capitalized upon recent advances in linear dynamical network control theory to calculate the energetic cost necessary to activate the fronto-parietal system through the control of multiple brain regions given existing structural network topology. We found that the energy required to activate the fronto-parietal system declined with development, and the pattern of regional energetic cost predicts unseen individuals’ brain maturity. Finally, energetic requirements of the cingulate cortex were negatively correlated with executive performance, and partially mediated the development of executive performance with age. Our results reveal a mechanism by which structural networks develop during adolescence to reduce the theoretical energetic costs of transitions to activation states necessary for executive function.

AB - Executive function develops during adolescence, yet it remains unknown how structural brain networks mature to facilitate activation of the fronto-parietal system, which is critical for executive function. In a sample of 946 human youths (ages 8-23y) who completed diffusion imaging, we capitalized upon recent advances in linear dynamical network control theory to calculate the energetic cost necessary to activate the fronto-parietal system through the control of multiple brain regions given existing structural network topology. We found that the energy required to activate the fronto-parietal system declined with development, and the pattern of regional energetic cost predicts unseen individuals’ brain maturity. Finally, energetic requirements of the cingulate cortex were negatively correlated with executive performance, and partially mediated the development of executive performance with age. Our results reveal a mechanism by which structural networks develop during adolescence to reduce the theoretical energetic costs of transitions to activation states necessary for executive function.

KW - Adolescence

KW - Development

KW - Diffusion MRI

KW - Energy

KW - Network

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JO - eLife

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ER -

Optimization of energy state transition trajectory supports the development of executive function during youth

Abstract

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Keywords

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